Project description:Zinc deficiency during pregnancy and postnatal life can adversely affect the health and predispose to an increased risk of developing human diseases at adulthood. The present study was designed to evaluate whether dietary zinc deficiency or supplementation during the pregnancy, lactation and juvenile stages interferes with the development of mammary tumors induced by 7,12-dimethylbenzanthracene (DMBA) in female Sprague-Dawley (SD) rats. Pregnant females SD were allocated into three groups: dams received diets containing adequate (35 mg/Kg chow), deficient (3 mg/Kg chow) or supplemented (180 mg/Kg chow) zinc levels during gestational day 10 (GD 10) until the litters weaning. Female offspring were allocated into three groups and received the same diets as their dams until postnatal day (PND) 51. At PND 51, females SD (n=16 each group) received a single dose of DMBA (50 mg/kg, ig) for initiation of mammary carcinogenesis, adequate zinc diets and were euthanized at PND 180. Tumors samples were collected and processed for histological evaluation and microarray analysis. Dietary zinc deficiency induced a significant reduction in female offspring body weight evolution at parturition, weaning and pubertal phases. At late in life, the early in life dietary zinc deficiency or supplementation did not alter the latency, incidence, multiplicity and volume or histological types of mammary tumors in relation to the adequate zinc group, and changed the expression of a small amount of genes. The present findings indicate that early-in life dietary zinc deficiency or supplementation did not significantly modify the susceptibility to development of mammary tumors induced by DMBA.

Project description:Some previous experimental studies have shown that early in life intake of high-fat or Western-style diets did alter the development of mammary cancer in adulthood female rats. Thus, the present study investigated the distinct gene expression patterns of chemically induced mammary tumors derived from female offspring whose dams intake control diet (CD) or Western-style diet (WD). During gestational days (GD) 12-21 and post-natal days (PND) 1-21, pregnant Sprague-Dawley (SD) rats were fed a CD diet or WD (high-fat and low-fiber and oligoelements) diet. On postnatal day (PND) 21, the female offspring received a single dose of carcinogen N-Methyl-N-Nitrosourea (MNU, 50 mg/kg) and CD diet for 12 weeks. Latency, incidence and tumor burden were registered. Mammary tumors samples were collected and histopathology and gene expression analysis were performed.

Project description:Rodent studies have indicated that gestational and perinatal bisphenol A (BPA) exposure increase the risk of developing breast cancer during adulthood. In contrast, some dietary compounds such as genistein (GEN) and indole 3-carbinol (I3C) present potential protective effects against inducing hormone-dependent cancers, including that of the mammary gland. Thus, we aimed to evaluate the role of these dietary compounds on early mammary gland development and carcinogenesis in female Sprague-Dawley offspring. Pregnant Sprague-Dawley (SD) rats were treated with BPA at 25 or 250µg/kg b.w./day by gavage from gestational day (GD) 10 to 21 with or without dietary GEN (250 mg/kg chow, ~5.5 mg/kg b.w./day) or I3C (2000 mg/kg chow, ~45.0 mg/kg b.w./day). At post-natal day (PND) 21, some female offspring from different litters were euthanized for mammary gland development and gene expression analyses while other female offspring received a single dose of N-methyl-N-nitrosourea (MNU) for mammary carcinogenesis initiation. The findings this study indicated the prenatal exposure to BPA, GEN and I3C did not significantly alter ductal elongation, number of terminal end buds (TEB) or cell proliferation, and estrogen receptor alpha (ER-α) immunostaining expression in epithelial mammary cells at PND 21. BPA treatment modulated the expression of several genes, but these changes were not associated with a dose dependent response. Dietary GEN and I3C treatment causally and consistent with the mammary gland structures outcomes. Besides, maternal BPA exposure associated with dietary GEN and I3C did not alter the susceptibility to the mammary cancer development in adulthood when the carcinogen was administered in a window of immature mammary gland development.

Project description:Nutritional status influences feeding behaviors, food preferences and taste sensations. For example, zinc-deficient rats have been reported to show reduced and cyclic food intake patterns with increased preferences for NaCl. Although some impairments of the central nervous and endocrine systems have been speculated to be involved in these phenomena, the effects of short-term zinc deficiency on the brain have not been well examined to date. In this study, we performed a comprehensive analysis of the gene expression patterns in the rat diencephalon, which is a portion of the brain that includes the hypothalamus and thalamus, after short-term zinc deficiency and also during zinc recovery. The rats showed reduced and cyclic food intake patterns with increased salt preferences after a 10-day dietary zinc deficiency. A comparative analysis of their diencephalons using cDNA microarrays revealed that approximately 1% of the genes expressed in the diencephalons showed significantly altered expression levels. On the other hand, a 6-day zinc supplementation following the deprivation allowed for the recovery to initial food intake behaviors and salt preferences. The expression levels of most of the genes that had been altered by exposure to zinc deficient conditions were also recovered. These results show that feeding behaviors, taste preferences and gene expression patterns in the diencephalon respond quickly to changing zinc levels. This suggests that the gene expression changes observed in the diencephalon and the accompanying functional changes may be related to the development of deviations in feeding behaviors and increased preferences for NaCl in zinc-deficient rats.

Project description:Nutritional factors may have a role on mammary carcinogenesis. Here we study the role dietary lipids on gene expression profile of DMBA-induced mammary tumors in Sprague-Dawley rats

Project description:The linkage between nutrition and cancer prevention is an intriguing concept that is gaining widespread support based on epidemiological and animal studies. Multiple mechanisms likely underlie dietary protection against cancer, with effects influenced by target tissue response, cell-cell interactions and developmental context. Given the negative correlation between breast cancer incidence and intake of soy foods by Asian women, and the increasing consumption of soy protein-based formula by infants in the Western world, we have studied soy protein isolate (SPI) used in most infant formula as a paradigm to evaluate diet as a risk factor in a rodent model of mammary cancer. We previously demonstrated that lifetime exposure to dietary SPI reduced the incidence of N-methyl-N-nitrosourea-induced mammary tumors in young adult rats relative to those fed the control diet Casein (CAS). This protection was associated with increased tumor suppressor PTEN and decreased Wnt signaling component expression in mammary epithelial cells at postnatal day (PND) 50 prior to carcinogen insult. To identify early events contributing to mammary tumor suppression by diet, we used Affymetrix RAE230A GeneChips containing 14280 probe sets and the GeneSpring Robust Multi-array program to analyze genomic profiles of mammary glands of prepubertal (PND21) rats lifetime exposed to SPI or CAS. Experiment Overall Design: Female SD rats are exposed to either casein/soy protein isolate based AIN-93G diet since gestation day 4 till weaning. Whole mammary gland were harvested for the gene analysis by microarray.

Project description:Cross-species hybridization analysis of mammary glands during pregnancy and lactation. Results provide insight into putative conserved molecular mechanisms regulating mammary gland development. This study was performed to identify orthologous transcripts that are differentially co-expressed in the mammary gland at 2 stages of development (pregnancy and lactation) in wild type Sprague-Dawley rats. Key points are examined in a time series of Sprague Dawley rat mammary gland development, secretory activation and lactation. Triplicate rat (three biological replicates) at each time point were used for statistical power totalling 12 individual arrays in this study. Rats were as staged pregnant day 1 the day that post coital plug was observed, and similarly, lactation day 1 was the first day after birth. Whole mammary glands No. 4 (inguinal) were obtained from female rats at stages of development: virgin (adulthood, 14 wks of age), Pregnant (5 and 14 days of pregnancy) and Lactating (day 1 and 12 postpartum). The two-color (Cy5/Cy3) microarray experiment was designed to hybridize samples from each group against a common reference, a pool of RNA from mammary gland of three parous or virgin female rats.

Project description:Nutritional status influences feeding behaviors, food preferences and taste sensations. For example, zinc-deficient rats have been reported to show reduced and cyclic food intake patterns with increased preferences for NaCl. Although some impairments of the central nervous and endocrine systems have been speculated to be involved in these phenomena, the effects of short-term zinc deficiency on the brain have not been well examined to date. In this study, we performed a comprehensive analysis of the gene expression patterns in the rat diencephalon, which is a portion of the brain that includes the hypothalamus and thalamus, after short-term zinc deficiency and also during zinc recovery. The rats showed reduced and cyclic food intake patterns with increased salt preferences after a 10-day dietary zinc deficiency. A comparative analysis of their diencephalons using cDNA microarrays revealed that approximately 1% of the genes expressed in the diencephalons showed significantly altered expression levels. On the other hand, a 6-day zinc supplementation following the deprivation allowed for the recovery to initial food intake behaviors and salt preferences. The expression levels of most of the genes that had been altered by exposure to zinc deficient conditions were also recovered. These results show that feeding behaviors, taste preferences and gene expression patterns in the diencephalon respond quickly to changing zinc levels. This suggests that the gene expression changes observed in the diencephalon and the accompanying functional changes may be related to the development of deviations in feeding behaviors and increased preferences for NaCl in zinc-deficient rats. Four-week-old male Sprague-Dawley rats were purchased from Charles River Japan (Yokohama, Japan). Fifteen rats were individually housed in a stainless steel cage in a room with constant humidity at 22 ± 1 °C under a 12 h light-dark cycle (lights on at 8:00). Zinc-deficient diets (# D19488M, Research Diets, New Brunswick, NJ, USA) were based on the AIN-93G diet and contained 0.6 mg zinc / 1000 g diet (Table 1). For the control zinc-sufficient diets, zinc sulfate supplements were provided with up to 30.0 mg zinc / 1000 g diet. Rats were fed the control diets ad libitum for 1 week for adaptation and then were divided into two groups matched for body weight. For the zinc-deficient experiment, rats in the ZD group (n =9) were allowed to eat the zinc-deficient diets ad libitum. The rats in the PF group (n = 6) were pair-fed the control diets to match the intake of the ZD rats. Two fluid bottles with deionized water were attached to each cage for the entire experiment with the exception of the 48 h preference test, in which 300 mM NaCl was provided from days 6 to 8. Zinc was limited for 10 days to reduce the effects of differences in salt intake in the preference test between the two groups. For the zinc recovery experiment, the ZR (n = 9) and ZRPF (n = 6) groups were subjected to the same conditions as above. Briefly, after 1 week of adaptation, ZR rats were fed the zinc-deficient diets ad libitum, and ZRPF rats were pair-fed the control diets for 10 days. After that, the rats in both the ZR and ZRPF groups were fed the fixed amount (13 g) of the control diets for the 6 day zinc recovery period to avoid any differences in food intake between the two groups that would be caused by pair-feeding because the previous report showed rapidly increased food intake following the initiation of the zinc-sufficient diets after zinc deficiency [1]. The diet amounts were restricted to the average consumption of the ZR group on the last day of the zinc-deficient period. The 48 h two-bottle preference tests for 300 mM NaCl were performed from days 6 to 8 during the deficient period and from days 14 to 16 during the recovery period. The analysis removed one rat from the ZRPF group showing more than a 0.5 of preference ratio to the 300 mM NaCl solution and three rats from the ZR group showing less than 0.5 preference ratios as assessed by a preference test that was conducted during days 6 to 8. At the end of each experiment, the rats were deeply anesthetized with pentobarbital sodium. Blood samples were collected from the carotid arteries and stored at -80 °C. The brains were quickly removed from the bodies after decapitation, and the diencephalons were separated by forceps on ice. The diencephalons were washed in ice-cold phosphate-buffered saline (PBS), treated with RNAlater (Invitrogen, Carlsbad, CA, USA), and stored at -20 °C. The serum zinc concentrations were analyzed with an ICP-AES (SPS 1200 VR, Seiko Instruments, Chiba, Japan). The Animal Care Committee of the University of Tokyo approved all animal experiments. Four average rats from each group were selected based on body weights, plasma zinc concentrations, and salt preferences.

Project description:Cancer effect of Zinc Deficiency on Esophagus in Rats: a miRNA profile study. 24 rats (Zinc sufficient n=8, Zinc Deficient n=4 and Zinc Replenished=12) were profiled for miRNAs study

Project description:We investigated whether dietary vitamin D supplementation can rescue the expression of genes that are dysregulated within the neocortex of Mecp2+/- mice, and whether vitamin D deficiency further exacerbates transcriptome disruptions in these mice. We found that dietary vitamin D modification has a profound impact on the transcriptome of the neocortex. We identified more than 200 differentially expressed genes whose expression is normalized with vitamin D supplementation, many of which are associated with neuronal morphology. Dietary vitamin D deficiency exacerbated the dysregulation of many of these genes in the Mecp2+/- cortex, but, strikingly, it normalized the expression of many other dysregulated genes, similar to the effect of supplementation.